1. Product Family Presentation: Introduction to CapSense® by Cypress
The Industry’s No. 1 Capacitive Sensing Technology

2. Capacitive Sensing Technology Enables Innovation
Items that have been updated based on TJR feedback have been indicated with a U
Capacitive Sensing Technology Enables Innovation
You can use capacitive sensing technology to create innovative and reliable products
Sleek, stylish and highly reliable capacitive sensing buttons can replace all of the 10 billion mechanical buttons sold every year
Capacitive sensing technology can implement reliable, proximity-based applications such as wake-on-approach, face detection and spatial measurement
Capacitive sensing technology can replace mechanical sensors for applications such as liquid-level sensing and frost detection
Capacitive User Interface in a Digital Boom Box by Logitech
Capacitive Sensing-Based Liquid-Level Sensor by Cambridge Consultants
Deliver innovative products with Cypress’s industry-leading capacitive sensing technology 3a

3. CapSense: The Industry’s Leading Capacitive Sensing Technology
CapSense is Cypress’s capacitive-sensing technology
CapSense is the industry’s No. 1 solution in sales by 4x over No.2
Over one billion CapSense controllers have replaced more than five billion mechanical buttons
CapSense is found everywhere, including smartphones, home appliances and printers
“We selected CapSense for its flexibility, as well as for its durability and performance, given the harsh operating environment that washing machines face. Having previously designed CapSense into our oven products, we are well aware of the stylish interfaces it enables for home appliances.”
- Davide Aloj, Electronic Development Manager, Indesit
Touch Buttons: 2003
Liquid Tolerance: 2008
Configurability: 2011
Noise Immunity: 2010
Cypress’s CapSense research and development begins with buttons and sliders
CapSense algorithms offer Liquid Tolerance, proximity sensing and improved noise immunity
SmartSense™ Auto-tuning revolutionizes CapSense design by removing Manual Tuning and improving noise immunity
CapSense Express™ offers configurable solutions that do not require Firmware Development
One billionth CapSense controller shipped with stylus-activated buttons
1B Units Shipped: 2013
LG Chocolate Mobile Phone
Whirlpool Dishwasher
Microsoft Arc Touch Mouse
HP TouchSmart Printer
Samsung Galaxy Note 3 3b

4. CapSense Technology Terms
Capacitance
The property of a conductive body, such as a copper trace on a PCB, to store an electric charge
Can increase or decrease because of manufacturing tolerances and environmental changes
Capacitive Sensing System
A system capable of measuring and responding to a change in Capacitance
Capacitive Sensor
A conductor and substrate, such as a copper button on a printed circuit board (PCB), which reacts to a touch or an approaching object with a change in capacitance
Sensor Layout The placement of Capacitive Sensors, for example, on a Printed Circuit Board (PCB)
Raw Count
A digital signal generated by a Capacitive Sensing System
The capacitance of a Capacitive Sensor is digitized into a Raw Count
Sensing Parameters
Parameters that define the response and performance of a Capacitive Sensing System, including
Sensitivity: The minimum Capacitance change measured by the Capacitive Sensing System (for example, 100 fF)
Baseline: The reference value against which changes in Capacitance are measured (for example, a Raw Count of 3,000)
Touch Threshold: The minimum Capacitance change needed to trigger a response from a Capacitive Sensing System (for example, a Raw Count change of 5,000) 4a

5. CapSense Technology Terms
Firmware Development
The process of developing algorithms in a programming language, such as the C language, to control the response of a Capacitive Sensing System with an embedded microcontroller
Manual Tuning
The manual process of setting Sensing Parameters for optimal performance during the design phase
Required on an ongoing basis to compensate for system, manufacturing and environmental changes during the prototyping and manufacturing phases
SmartSense Auto-tuning
A CapSense algorithm that automatically sets Sensing Parameters for optimal performance after the design phase
Continuously compensates for system, manufacturing and environmental changes
Parasitic Capacitance (CP)
The intrinsic Capacitance of the PCB traces, or other connections, to a Capacitive Sensor
Reduces the sensitivity of a Capacitive Sensor by attenuating the sensor signal
Signal-to-Noise Ratio (SNR)
The ratio of the sensor signal, when touched, to the noise signal of an untouched sensor
Capacitive Sensing Systems require an SNR of 5:1 per IEC standard /6-1
Electromagnetic Interference (EMI)
May degrade the performance of a Capacitive Sensing System
Systems must meet IEC /6-1 standards for immunity to external noise (“Radiated Immunity”)
May be emitted by the Capacitive Sensing System
Systems must meet IEC noise standards (“Radiated Emission”) 4b

6. CapSense Technology Terms
Liquid Tolerance
The ability of a Capacitive Sensing System to work properly in the presence of liquid droplets, streaming liquids or mist
Proximity Sensor
A sensor that can detect the presence of nearby objects without any physical contact
Glove Touch
The ability of a Capacitive Sensing System to detect touches by a user wearing gloves, which degrade performance
Stylus Touch
The ability of a Capacitive Sensing System to detect touches by a pointed, handheld instrument 4c

7. Design Problems Engineers Face
1. Mechanical buttons are old-fashioned and unreliable
Consumers demand reliable products with sleek aesthetics
Mechanical buttons and knobs are bulky and unattractive, and wear out over time
Legacy Keypad With Mechanical Buttons
Mechanical buttons get dirty and sticky
Calculator With Membrane Switches
Membrane switches wear out 5a

8. Design Problems Engineers Face
2. Reliable Capacitive Sensing Systems are difficult to implement
Capacitive Sensing Systems require specialized expertise to implement
Curved or thick overlays, gloves and stylus sensing reduce SNR performance
End applications require time-consuming Manual Tuning for robust performance
EMI noise sources can cause failures
Curved Overlays on a Wearable Device
Glove Touch for Medical Equipment
Products with rounded and seamless edges are becoming increasingly popular with consumers. The curved overlays on these products require a high SNR.
Doctors and technicians generally wear gloves while operating medical equipment. Glove Touch requires a high SNR. 5b

9. Design Problems Engineers Face
3. Advanced features such as proximity sensing and Liquid Tolerance can further complicate the system design
Noise can make it more difficult to implement reliable proximity sensing solutions
Water, mist and other liquids trigger false touches in Capacitive Sensing Systems
Advanced features require additional ICs and passives, which increase the design complexity and BOM
Capacitive Sensing System in a Washing Machine
Capacitive Sensing Systems are prone to failure in the presence of water
Proximity Sensor on a Computer Mouse
A Proximity Sensor can be used to turn a mouse on when a user’s hand approaches, but it is susceptible to EMI 5c

10. Design Problems Engineers Face
4. Mechanical and analog sensors are expensive and can be unreliable
The failure rate of mechanical devices is much higher than that of electronic devices
Analog sensors can fail in challenging environments, such as at high temperatures or near liquids
Mechanical Liquid-Level Sensor
Infrared (IR) Proximity Sensor
Mechanical liquid-level sensors are expensive and have multiple parts, including floats, that can fail or wear out
Analog IR sensors often fail at high temperatures or in strong ambient light 5d

11. CapSense Solves These Problems
Replaces mechanical buttons with sleek and reliable CapSense buttons at low cost Provides SmartSense Auto-tuning and superior SNR (>100:1), which make reliable Capacitive Sensing Systems easy to implement Provides advanced features like proximity sensing and Liquid Tolerance simply and quickly Replaces mechanical and analog sensors with reliable, cost-effective Capacitive Sensors CapSense enables a reliable, easy-to-implement Capacitive Sensing System with advanced features
CapSense enables an attractive and reliable cooktop with a flat, easy-to-clean, liquid-tolerant surface
Legacy Cooktop Controls
Mechanical knobs in legacy cooktops are bulky and unattractive
Induction Cooktop by Cooktek 5e

12. CapSense Replaces Mechanical Buttons
How CapSense registers a touch
A Capacitive Sensor is used to measure the change in Capacitance between a pin and the ground
CapSense algorithms and analog circuitry convert the measured Capacitance to a Raw Count
A finger touch increases the Capacitance of the system, which in turn increases the Raw Count
An increase in the Raw Count above a user-defined Touch Threshold registers a touch
Refer to the Getting Started With CapSense Guide for details on CapSense algorithms
Capacitive Sensor Without a Finger Touch
Capacitive Sensor With a Finger Touch
Raw Count Variation on Finger Touch
No Touch
Touch
No Touch
1,700
Touch Threshold
1,650
Overlay
Overlay CF
1,600
Signal
Raw Count
Copper
Ground CP
Capacitive Sensor CP
Copper
Ground
Copper
Ground CP
Capacitive Sensor CP
Copper
Ground
PCB
PCB
1,550
Noise
CX = 2CP
CX = 2CP + CF
1,500
Baseline
400
800
1,200
1,600
Time (ms)
CX = Total Capacitance measured by the Capacitive Sensing System
CP = Parasitic Capacitance
CF = Capacitance added by a finger touch
CF is dependent on the overlay material, overlay thickness and the dimensions of the finger (typical = 9mm) and sensor
CapSense algorithms use analog circuits to convert the Capacitance to Raw Count, which is compared to the chosen Touch Threshold to record a touch 6a

13. SmartSense Auto-tuning Saves Time
SmartSense Auto-tuning sets, monitors and continuously maintains optimal Capacitive Sensor performance
Reduces design effort by eliminating Manual Tuning after the design phase
Adapts to manufacturing variations in PCB, overlay and paint that degrade touch-sensing performance
Adapts to changes in system environment due to RF noise sources
Allows a platform design approach that uses different overlays, button shapes and Trace Lengths with the same electronics
SmartSense Auto-tuning Cuts Design Cycle Time
Steps eliminated through Auto-tuning functionality
SmartSense Auto-tuning eliminates time-consuming Manual Tuning and the design iterations caused by it 6b

14. Why CapSense “Just Works”
High SNR: CapSense exceeds the requirements for robust performance
Enables system designs with an SNR >100:1, greater than the IEC requirement of 5:1
Enables designs with thick or curved overlays
Enables advanced features such as Glove Touch and Stylus Touch support
Noise immunity: CapSense meets all of the IEC standards
CapSense buttons “just work” because of rigorous engineering and testing
Radiated Immunity Test Room
Radiating Antenna
CapSense Test Board
Test Parameter
Parasitic Capacitance
Overlay
Glove Thickness
CapSense SNR
(IEC Spec = 5:1)
Reference
10 pF
1.0 mm
None
150:1
Thick Overlay
2.0 mm
73:1
Glove Touch
4 mm
37:1
Thick Overlay and Glove Touch
25:1
Cypress setup to test the EMI tolerance of CapSense buttons
Radiated Emission Test Data 40 30 20 10
100
1,000
Frequency (MHz)
Electric Field Strength (dBµV/m) 50 60 70
IEC limit
Actual CapSense data
IEC Standard
Description
IEC Standard Requirement
CapSense
/6-1
Radiated immunity
(80 MHz to 2.4 GHz)
SNR > 5:1, No false trigger, > 10V/m
10:1 SNR, No false triggers
Radiated emission
30.0 dBµV/m, MHz
37.5 dBµV/m, 230-1,000 MHz
< 25 dBµV/m
< 37 dBµV/m 6c

15. How Proximity Sensing Works
CapSense Sensing Parameters can be set to sense a finger without an actual touch
A finger near a highly sensitive Capacitive Sensor increases the Capacitance of a Capacitive Sensing System
Proximity Sensor performance can be improved by optimizing the board layout and Firmware Development
Multiple Proximity Sensors can be implemented on the same board to improve the overall performance
Refer to the Proximity Sensing with CapSense Application Note for details on proximity sensing
Proximity Sensor Without a Finger Nearby
Proximity Sensor With a Finger Nearby
Raw Count Variation With a Finger Nearby
No Touch
Touch
No Touch
40,600
Touch Threshold
Overlay
Overlay
CFP
40,400
Signal
Copper
Ground
Raw Count CP
Capacitive Sensor CP
Copper
Ground
Copper
Ground CP
Capacitive Sensor CP
Copper
Ground
40,200
PCB
PCB
Noise
40,000
CX = 2CP
CX = 2CP + CFP
Baseline
400
800
1,200
1,600
Time (ms)
CX = Total Capacitance measured by the Capacitive Sensing System
CP = Parasitic Capacitance
CFP = Capacitance added to the system by a nearby finger
CFP is dependent on the overlay material, overlay thickness, sensor size and the distance of the finger from the sensor
The increase in Raw Count of a Proximity Sensor when a finger approaches is similar to the increase when a finger touches a Capacitive Sensor 6d

16. CapSense Proximity Sensors
CapSense enables capacitive Proximity Sensors with:
A proximity sensing distance of up to 30 cm
Superior SNR and SmartSense Auto-tuning to ensure reliable performance
CapSense Proximity Sensors enable:
Aesthetic design with proximity-based LED lighting effects
Enhanced reliability by eliminating mechanical contact
Lower power consumption than other Proximity Sensors, such as IR sensors
Advanced features such as wake-on-approach, face detection and spatial measurement
Wake-on-Approach in Light Control Panels
Face Detection in Nokia Asha 502
Spatial Measurement Using Multiple Proximity Sensors
The wake-on-approach feature turns on the Capacitive Sensing System from the standby mode.
The face-detection feature prevents false touches on the phone’s touchscreen.
Spatial measurement uses multiple Proximity Sensors to measure position and distance.
Proximity Sensors 6e

17. CapSense Works Under Liquids
CapSense maintains touch accuracy in wet conditions by using:
A shield electrode to eliminate false touches from water droplets, mist and other liquids
A guard sensor to eliminate false touches from streaming liquids or submersion
Watch our Liquid Tolerance demo video to learn more
Liquid-Tolerant CapSense Sensor Layout
Sensor
Shield Electrode
Guard Sensor
Shield electrodes are copper fills around sensors that offset liquid droplets; guard sensors are copper traces that offset streaming liquids
Raw Count Without a Shield Electrode
Raw Count With a Shield Electrode
CapSense Works Under Liquids
Finger Touch
Water Droplet
Finger Touch
Touch Threshold
Touch Threshold
Water Droplet
Noise Floor
Noise Floor
The Raw Count generated by a water droplet exceeds the Touch Threshold, causing a false touch
The Raw Count generated by a water droplet is below the Touch Threshold; therefore, there is no false touch
CapSense buttons even work under spaghetti sauce 6f

18. CapSense Liquid Sensing
Capacitive Sensors can detect liquid-level height and other liquid characteristics
Liquids in contact with a Capacitive Sensor increase the Capacitance of the Capacitive Sensing System
The increase in Capacitance is dependent on the liquid’s characteristics, such as its concentration
Capacitive Sensors can sense different types of liquids, such as water, milk and automobile coolants
Typical applications include liquid-level sensing, and detection of concentration changes and frost
Refer to the Getting Started with CapSense Guide for details on CapSense-based liquid sensing
Capacitive Sensor Without Any Liquid in Contact
Capacitive Sensor With a Liquid in Contact
Raw Count Variation on Liquid Contact
No Touch
Touch
No Touch
1,700
Touch Threshold
Liquid
1,650
Overlay
CX = 2CP + CL
PCB
Overlay CP
Copper Ground
Copper Ground CL
Capacitive Sensor
1,600
Signal
Raw Count
Copper
Ground CP
Capacitive Sensor CP
Copper
Ground
PCB
1,550
Noise
1,500
CX = 2CP
Baseline
400
800
1,200
1,600
Time (ms)
CX = Total Capacitance measured by the Capacitive Sensing System
CP = Parasitic Capacitance
CL = Capacitance added to the system by the liquid
CL is dependent on the overlay material, overlay thickness and the characteristics of the liquid
The increase in Raw Count when a Capacitive Sensor is in contact with a liquid is similar to the increase when a finger touches a Capacitive Sensor 6g

19. NDA Required Contact Sales NDA Required Contact Sales
CapSense® Portfolio
CapSense Express™
CapSense Plus™
PSoC®
Configurable Controllers1
Programmable Controllers2
Programmable System-on-Chip2
NEW
CY8CMBR3106S 11 Buttons, 2 Sliders Proximity, Liquid Tolerance SmartSense_EMCplus™3
CY8CMBR Buttons, 8 LEDs Proximity, Liquid Tolerance SmartSense_EMCplus3
NEW
NEW
CY8C4246/7
96 Buttons, 19 Sliders
NDA Required Contact Sales
CY8C56xx/58xx 62 Buttons, 12 Sliders
64, 128, 256KB Flash Proximity, Liquid Tolerance SmartSense_EMCplus3
NEW
CY8CMBR Buttons, 4 LEDs Proximity, Liquid Tolerance SmartSense_EMCplus3
CY8CMBR Buttons, 5 LEDs Proximity, Liquid Tolerance SmartSense_EMCplus3
NEW
CY8C20xx7 31 Buttons, 6 Sliders 16, 32KB Flash
Proximity, Liquid Tolerance
SmartSense™ Auto-tuning
CY8C52xx/54xx 62 Buttons, 12 Sliders
32, 64, 128, 256KB Flash Proximity, Liquid Tolerance SmartSense_EMCplus3
CY8C36xx/38xx 62 Buttons, 12 Sliders
32, 64KB Flash Proximity, Liquid Tolerance SmartSense_EMCplus3
NEW
CY8CMBR Buttons, Proximity SmartSense_EMCplus3
CY8CMBR Buttons, 10 LEDs SmartSense Auto-tuning
CY8C20xx6A/S 33 Buttons, 6 Sliders 16, 32KB Flash, 2KB SRAM SmartSense Auto-tuning
CY8C32xx/34xx 62 Buttons, 12 Sliders
16, 32, 64KB Flash Proximity, Liquid Tolerance SmartSense_EMCplus3
NEW
CY8C4xxx-BL 36 Buttons, 7 Sliders
128, 256KB Flash, BLE4 Proximity, Liquid Tolerance SmartSense_EMCplus3
Q414
Performance
CY8CMBR310XLP
4 Buttons, Low Power
NDA Required Contact Sales
CY8CMBR Buttons SmartSense Auto-tuning
CY8C20xx6H 25 Buttons, 5 Sliders 8, 16KB Flash
SmartSense Auto-tuning
Haptics
CY8C21x34/B 24 Buttons, 4 Sliders 8KB Flash
Proximity, Liquid Tolerance
SmartSense Auto-tuning
CY8C41xx/42xx 36 Buttons, 7 Sliders
16, 32KB Flash Proximity, Liquid Tolerance SmartSense_EMCplus3
CY8CMBR Buttons, 4 LEDs SmartSense™ Auto-tuning
CY8CMBR Buttons, 10 LEDs SmartSense Auto-tuning
CY8C20x36A 33 Buttons, 6 Sliders 8KB Flash SmartSense Auto-tuning
CY8C28xx 44 Buttons, 8 Sliders 16KB Flash Proximity, Liquid Tolerance SmartSense Auto-tuning
CY8CMBR Buttons, 2 LEDs SmartSense_EMCplus3
NEW
CY8C201xx 10 Buttons, 5 LEDs 2 Sliders
CY8C20x34 25 Buttons, 6 Sliders
8KB Flash
NEW
CY8C40xx 16 Buttons, 3 Sliders
8, 16KB Flash Proximity, Liquid Tolerance SmartSense_EMCplus3
Integration
1 Standard products that are configured for target applications with a graphical user interface Bluetooth Low Energy
2 Microcontroller-based products that can be freely programmed to implement additional functions
3 SmartSense Electromagnetic Compatible = SmartSense Auto-tuning + high noise immunity
Production
Development
QQYY
Availability
Sampling
Concept
Status
10a

20. CapSense Design Resources
Use the CapSense design software and kits to easily implement your CapSense design
Download datasheets, design guides and application notes:
Contact our dedicated team of technical experts to support your design:
CapSense Solution
Design Software
CapSense Kits
CapSense Express
EZ-Click
MBR3 Evaluation Kit
CapSense, PSoC 1
PSoC Designer
CapSense Starter Kit
PSoC 3, PSoC 4, PSoC 5LP
PSoC Creator
PSoC 4 Pioneer Kit
Noisy and Wet Conditions
PSoC Designer
CapSense Starter Kit With a MiniProg3 Programmer Kit
Refrigerator UI by Panasonic
A complex design in challenging environments…
Is simplified using EZ-Click, PSoC Designer, or PSoC Creator…
And prototyped on a CapSense Kit…
To create a reliable, one-chip CapSense solution.
10b

21. CapSense Express Solution Example – Security Keypad
CapSense Value
Block Diagram
Design Problems
Quickly add capacitive buttons to an unmodified design
Ensure robust performance even in a noisy environment
Ensure robust operation in wet conditions like mist or rain
Implement a wake-on-approach feature to wake the system from sleep when a hand approaches
CapSense Express Solution
Is an easy-to-implement solution
Provides superior noise immunity (SNR >100:1)
Enables a liquid-tolerant design
Uses a Proximity Sensor for wake-on-approach
Cypress CapSense 16
CapSense One-Chip MBR Solution
I2C 2
Capacitive Button Keypad with Proximity Sensors
Host
Integrated
SmartSense
Algorithm
CapSense Design Resources
Design Software: EZ-Click
Kit: MBR3 Evaluation Kit
Design Guides: Getting Started with CapSense
CapSense MBR3 Design Guide
Security Keypad
by Samsung
CapSense provides a sleek and robust design
11a

22. CapSense Solution Example – Espresso Machine
CapSense Value
Block Diagram
Design Problems
Implement capacitive sensing in a noisy environment
Ensure robust operation in wet conditions
Reduce BOM costs
CapSense Solution
Provides superior noise immunity (SNR >100:1)
Enables a liquid-tolerant design
Integrates additional functions like Proximity Sensors, an LED display, and buzzers
One-chip = CapSense + Proximity + LED + Buzzer
GPIO
Door Lock
I2C
PWM
M8C
MCU
CapSense One-Chip Solution
LED
Host
Button
Proximity
Capacitive Sensors 15 2
Integrated
SmartSense
Algorithm
Piezo Speaker
CapSense Design Resources
Design Software: PSoC Designer
Kits: CapSense Starter Kit
PSoC MiniProg3 Programmer Kit
Design Guides: Getting Started with CapSense
CY8C20xx7/S Design Guide
Espresso Machine
by Saeco
CapSense enables a sleek interface that works robustly in wet conditions
11b

23. Proximity Sensors for Face Detection
CapSense Solution Example –
Smartphone
CapSense Value
Block Diagram
Design Problems
Replace expensive IR sensors for face detection
Ensure robust button performance, even in noisy conditions
Work properly in the presence of mist or rain
CapSense Solution
Enables face detection with Proximity Sensors
Provides superior noise immunity (SNR >100:1)
Enables a liquid-tolerant design
M8C MCU
CapSense One-Chip Solution
I2C 2
Capacitive Sensors
Host 3
Integrated
SmartSense
Algorithm
Proximity Sensors for Face Detection 2
CapSense Design Resources
Design Software: PSoC Designer
Kits: CapSense Starter Kit
PSoC MiniProg3 Programmer Kit
Design Guides: Getting Started with CapSense
CY8C20xx7/S Design Guide
Android Buttons on a Smartphone by Oppo
CapSense enables a smartphone to work in wet conditions such as mist or rain
11c

24. Induction Drive Module
PSoC Solution Example –
Induction Cooktop
CapSense Value
Block Diagram
Design Problems
Implement capacitive touch in a noisy environment
Ensure robust operation when touched by wet fingers
Implement Class B certification1 for safe cooktop control
Reduce overall BOM
PSoC Solution
Provides superior noise immunity (SNR >100:1)
Enables a liquid-tolerant design
Provides Class B firmware library to simplify UL certification
Integrates additional functions, such as sensors, RTC, and an LED display, on the same chip
One-chip = MCU + CapSense + Logic + Analog + Display
PWM
Logic
Piezo Speaker
LED Display
UART
PSoC 3 One-Chip Solution
Induction Drive Module 7 2
AMUX
ADC
Humidity Sensor
8051 MCU 8
Integrated
SmartSense
Algorithm
RTC
Thermometer
Capacitive Sensors
CapSense Design Resources
Design Software: PSoC Creator
Kit: PSoC 3 CY8CKIT-030 Kit
Design Guides: Getting Started with CapSense
PSoC 3 CapSense Design Guide
App Note: IEC Class B Safety Software Library
Induction Cooktop by Midea
CapSense enables a sleek interface with Class B certification and low BOM costs
1 Class B certification is an IEC/UL safety standard for appliance operation. It is required by most home appliance manufacturers in the U.S. and Europe.
11d

25. CapSense Solution Example – Liquid-Level Sensing in a Coffee Machine
CapSense Value
Block Diagram
Design Problems
Eliminate mechanical parts, like floats, that tend to wear out
Accurately measure the level of milk in a container
Eliminate all sensors inside the container
CapSense Solution
Replaces liquid-level sensors with Capacitive Sensors
Accurately measures up to 0.2 cm
Enables Capacitive Sensors to be mounted outside the container
CapSense One-Chip Solution
M8C
MCU
Liquid
Level 2
Container
Host
I2C
Integrated
SmartSense
Algorithm 8
Capacitive
Sensors
CapSense Design Resources
Liquid-Level Sensing in a Coffee Machine by Gaggia
Design Software: PSoC Designer
Kits: CapSense Starter Kit
PSoC MiniProg3 Programmer Kit
Design Guides: Getting Started with CapSense
CY8C20xx7/S Design Guide
CapSense enables accurate measurement of the level of milk in a coffee machine
11e

26. Getting Started with CapSense
Buy the $25 MBR3 Evaluation Kit (CY3280-MBR3):
Install the EZ-Click software on your PC:
Download our Getting Started with CapSense Design Guide:
Attend a CapSense Workshop:
CY3280-MBR3 Evaluation Kit
Galaxy S5 by Samsung
Flyer Tablet by HTC
Voyager Bluetooth Headset by Plantronics 12

27. APPENDIX 15

28. References and Links CapSense Home Page: www.cypress.com/CapSense
Introduction to CapSense Workshop:
Getting Started with CapSense Design Guide:
CY8C20xx7/S CapSense Design Guide:
Proximity Sensing with CapSense App Note:
CapSense MBR3 Evaluation Kit (CY3280-MBR3) Page:
CapSense Proximity Shield (CY8CKIT-024) Page:
CapSense Starter Kit (AEK-CY8C20xx7) Page:
PSoC 4200 Pioneer Kit (CY8CKIT-042) Page:
PSoC 3 Development Kit (CY8CKIT-030) Page:
EZ-Click Page:
PSoC Designer Page:
PSoC Creator Page:
Cypress Product Roadmap: 18